/* * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <general_test/basic_audio_test.h> #include <shared/send_message.h> using nanoapp_testing::sendFatalFailureToHost; using nanoapp_testing::sendSuccessToHost; namespace general_test { namespace { //! Unit conversion nanoseconds per second. constexpr uint64_t kNanosecondsPerSecond = 1000000000; //! This is a reasonably high limit on the number of audio sources that a system //! would expose. Use this to verify that there are no gaps in the source //! handles. constexpr uint32_t kMaxAudioSources = 128; //! This is a reasonably high limit on the sample rate for a source that the //! system would expose. Sampling rates above 96kHz are likely to be too high //! for always-on low-power use-cases. Yes, this omits 192kHz, but that is //! generally reserved for professional audio/recording and mixing applications. //! Even 96kHz is a stretch, but capping it here allows room to grow. Expected //! values are more like 16kHz. constexpr uint32_t kMaxAudioSampleRate = 96000; //! Provide a floor for the sampling rate of an audio source that the system //! would expose. Nyquist theorem dictates that the maximum frequency that can //! be reproduced from given sequence of samples is equal to half that of the //! sampling rate. This sets a lower bound to try to detect bugs or glitches. constexpr uint32_t kMinAudioSampleRate = 4000; //! Provide a floor for buffer duration. This ensures that at the maximum //! sample rate possible, a minimum number of samples will be delivered in //! a batch. constexpr uint64_t kMinBufferDuration = (kNanosecondsPerSecond / kMaxAudioSampleRate) * 10; //! Provide a ceiling for the maximum buffer duration. This is to catch buggy //! descriptors of audio sources who expose very long buffers of data which are //! not practical for always-on, low-power use-cases. constexpr uint64_t kMaxBufferDuration = kNanosecondsPerSecond * 120; /** * @return true if the character is ASCII printable. */ bool isAsciiPrintable(char c) { // A simple enough test to verify that a character is printable. These // constants can be verified by reviewing an ASCII chart. All printable // characters that we care about for CHRE lie between these two bounds and are // contiguous. return (c >= ' ' && c <= '~'); } /** * @return true if the supplied string is printable, null-terminated and not * longer than the supplied length (including null-terminator). */ bool verifyStringWithLength(const char *str, size_t length) { bool nullTerminatorFound = false; bool isPrintable = true; for (size_t i = 0; i < length; i++) { if (str[i] == '\0') { nullTerminatorFound = true; break; } else if (!isAsciiPrintable(str[i])) { isPrintable = false; break; } } return (isPrintable && nullTerminatorFound); } /** * Validates the fields of a chreAudioSource provided by the framework and posts * a failure if the source descriptor is malformed. * * @return true if the source was valid. */ bool validateAudioSource(uint32_t handle, const struct chreAudioSource& source) { bool valid = false; if (!verifyStringWithLength(source.name, CHRE_AUDIO_SOURCE_NAME_MAX_SIZE)) { sendFatalFailureToHost( "Invalid audio source name for handle ", &handle); } else if (source.sampleRate > kMaxAudioSampleRate || source.sampleRate < kMinAudioSampleRate) { sendFatalFailureToHost( "Invalid audio sample rate for handle ", &handle); } else if (source.minBufferDuration < kMinBufferDuration || source.minBufferDuration > kMaxBufferDuration) { sendFatalFailureToHost( "Invalid min buffer duration for handle ", &handle); } else if (source.maxBufferDuration < kMinBufferDuration || source.maxBufferDuration > kMaxBufferDuration) { sendFatalFailureToHost( "Invalid max buffer duration for handle ", &handle); } else if (source.format != CHRE_AUDIO_DATA_FORMAT_8_BIT_U_LAW && source.format != CHRE_AUDIO_DATA_FORMAT_16_BIT_SIGNED_PCM) { sendFatalFailureToHost( "Invalid audio format for handle ", &handle); } else { valid = true; } return valid; } bool validateMinimumAudioSource(const struct chreAudioSource& source) { // CHQTS requires a 16kHz, PCM-format, 2 second buffer. constexpr uint32_t kRequiredSampleRate = 16000; constexpr uint64_t kRequiredBufferDuration = 2 * kNanosecondsPerSecond; // Ensure that the minimum buffer size is less than or equal to the required // size. return (source.sampleRate == kRequiredSampleRate && source.minBufferDuration <= kRequiredBufferDuration && source.maxBufferDuration >= kRequiredBufferDuration && source.format == CHRE_AUDIO_DATA_FORMAT_16_BIT_SIGNED_PCM); } /** * Attempts to query for all audio sources up to kMaxAudioSources and posts a * failure if a gap is found in the handles or the provided descriptor is * invalid. */ void validateAudioSources() { uint32_t validHandleCount = 0; bool previousSourceFound = true; bool minimumRequirementMet = false; for (uint32_t handle = 0; handle < kMaxAudioSources; handle++) { struct chreAudioSource audioSource; bool sourceFound = chreAudioGetSource(handle, &audioSource); if (sourceFound) { validHandleCount++; if (!previousSourceFound) { sendFatalFailureToHost( "Gap detected in audio handles at ", &handle); } else { bool valid = validateAudioSource(handle, audioSource); if (valid && !minimumRequirementMet) { minimumRequirementMet = validateMinimumAudioSource(audioSource); } } } previousSourceFound = sourceFound; } if (validHandleCount > 0) { if (!minimumRequirementMet) { sendFatalFailureToHost( "Failed to meet minimum audio source requirements"); } if (validHandleCount == kMaxAudioSources) { sendFatalFailureToHost( "System is reporting too many audio sources"); } } } } // anonymous namespace BasicAudioTest::BasicAudioTest() : Test(CHRE_API_VERSION_1_2), mInMethod(false), mState(State::kPreStart) {} void BasicAudioTest::setUp(uint32_t messageSize, const void * /* message */) { if (messageSize != 0) { sendFatalFailureToHost( "Beginning message expects 0 additional bytes, got ", &messageSize); } validateAudioSources(); sendSuccessToHost(); } void BasicAudioTest::handleEvent( uint32_t senderInstanceId, uint16_t eventType, const void* eventData) { if (mInMethod) { sendFatalFailureToHost("handleEvent() invoked while already in method."); } mInMethod = true; if (mState == State::kPreStart) { unexpectedEvent(eventType); } else { // TODO: Handle audio data from sources, perform basic sanity checks on it. } mInMethod = false; } } // namespace general_test